Wheeled folding bench with hand truck capabilities

ABSTRACT

A portable workbench includes top members, a support structure, a frame, wheels and a toe plate. The top members lie in a common plane and define a working surface with opposing side portions that define clamping surfaces. The support structure supports the top members and permits selectively traversing at least one of the pair of top members toward another to permit a workpiece to be clamped therebetween. The frame includes collapsible legs. The wheels and toe plate are coupled to the frame adjacent to each other. The workbench is positionable in a raised position, a collapsed position and a hand truck position. The toe plate is movable from a retracted position to an extended position to permit the portable workbench to be employed as a hand truck.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.11/487,785 filed on Jul. 17, 2006 which is a divisional applicationclaiming the benefit of U.S. patent application Ser. No. 10/911,778filed on Aug. 4, 2004, from which U.S. Pat. No. 7,090,210 issued, whichclaimed the benefit of U.S. Provisional Application No. 60/492,633,filed on Aug. 5, 2003. The disclosures of the above applications areincorporated herein by reference.

FIELD

The present disclosure relates to a workbench and more specifically to acollapsible portable workbench having a three member top defining a worksurface.

BACKGROUND

The statements in this section merely provide background informationrelated to the present disclosure and may not constitute prior art.

Workbenches incorporating a workpiece clamping device provide aconvenient structure to secure a workpiece while performing a toolingoperation. This type of clamping workbench generally includes a pair oftop members, one of which is fixed to a supporting structure, while theother is adjustable along the supporting structure toward and away fromthe first one of the top members by a screw-type handle translationdevice. One improvement on these clamping workbenches is a wheeled,collapsible frame that permits the workbench to be collapsed fortransport and thereafter wheeled to or from the job site.

Despite such improvements, there is a continued need for an efficientmeans by which one may transport their equipment to a job site. In thisregard, a tradesperson or do-it-yourselfer will frequently need totransport numerous tools and construction supplies to a job site inaddition to the collapsible workbench and as such, will typically makeseveral trips to and from the job site. Accordingly, there remains aneed in the art for a workbench with improved portability that permitsthe user to readily transport relatively large amounts of equipment andsupplies in addition to the workbench.

SUMMARY

In one form, the present disclosure provides a portable workbench havinga pair of top members, a support structure, a frame, a pair of wheelsand a toe plate. The top members lie in a common plane and define aworking surface with opposing side portions that define clampingsurfaces. The support structure supports the top members and includes aclamp for selectively traversing at least one of the pair of top memberstoward the other of said top members to permit a workpiece to beselectively clamped therebetween. The frame has a base, a pair of legs,which extend between the support structure and the base, and a linkagethat movably connects the support structure, said legs and said base.The linkage includes a pair of link members that are pivotally coupledat first ends to the support structure and slidably coupled at oppositesecond ends to an associated one of the legs. The wheels and the toeplate are coupled to the frame. The frame is positionable in a raisedposition and a collapsed position. The toe plate is movable from aretracted position to an extended position to permit the portableworkbench to be employed as a hand truck when the frame is positioned inthe collapsed position.

Further areas of applicability will become apparent from the descriptionprovided herein. It should be understood that the description andspecific examples are intended for purposes of illustration only and arenot intended to limit the scope of the present disclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings described herein are for illustration purposes only and arenot intended to limit the scope of the present disclosure in any way.

FIG. 1 is a front perspective view of a workbench constructed inaccordance with the teachings of the present disclosure, the workbenchbeing shown in a raised position;

FIG. 2 is a side view of the workbench of FIG. 1 with the workbenchbeing shown in an raised position;

FIG. 3 is a rear perspective view of the workbench of FIG. 1 with theworkbench being shown in a collapsed position;

FIG. 4 is a side view of the workbench of FIG. 1 with the workbenchbeing shown in a collapsed position;

FIG. 5 is a top view of a top member of the workbench of FIG. 1;

FIG. 6 is a bottom view of a top member;

FIG. 7 is a bottom perspective view of the top structure and supportstructure of the workbench of FIG. 1;

FIG. 8 is a rear view of the workbench of FIG. 1, with the workbenchbeing shown in an raised position;

FIG. 9 is a perspective view of a support member;

FIG. 10 is a plan view of a leg incorporated in the collapsible frame;

FIG. 11 is a perspective view of a second workbench constructed inaccordance with the teachings of the present disclosure illustrating theworkbench in a collapsed position and the toe plate in an extendedposition;

FIG. 12 is a perspective view of a portion of the workbench of FIG. 11illustrating the toe plate in a retracted position;

FIG. 13 is an enlarged view of a portion of FIG. 11 illustrating theconnection between the toe plate and the collapsible frame in greaterdetail;

FIG. 14 is a schematic view of a portion of the work bench of FIG. 11illustrating the use of an axle shaft for the common mounting of thewheels and the toe plate to the collapsible frame;

FIGS. 15 and 16 are schematic views that are similar to FIG. 14 butwhich illustrate alternate mountings of the wheels and the toe plate tothe collapsible frame;

FIG. 17 is an exploded view illustrating an alternate mounting of thetoe plate to the collapsible frame;

FIG. 18 is a section view taken through the toe plate and collapsibleframe of FIG. 17;

FIG. 19 is a top view of a portion of the workbench of FIG. 11illustrating the configuration of the handle assemblies in greaterdetail;

FIG. 20 is a rear perspective view of a workbench with hand truckconstructed in accordance with another aspect of the teachings of thepresent disclosure, the workbench with hand truck being shown in araised position;

FIG. 21 is a rear perspective view similar to FIG. 20 with the workbenchwith hand truck being shown in a hand truck position;

FIG. 22 is a perspective view similar to FIG. 20 with the workbench withhand truck being shown in a workbench operable position;

FIG. 23 is a perspective view similar to FIG. 22 with the workbench withhand truck being shown in a workbench open position;

FIG. 24 is a partial rear elevational view taken at elevation 4-4 ofFIG. 23;

FIG. 25 is a side elevational view taken at elevation 5-5 of FIG. 20;

FIG. 26 is a side elevational view of the workbench with hand truck ofthe present disclosure showing a partially rotated configuration betweenthe raised and workbench operable positions;

FIG. 27 is a side elevational view of the workbench operable position ofFIG. 22;

FIG. 28 is a rear perspective partially sectioned view of the crossmember release mechanism in an engaged position;

FIG. 29 is a rear perspective view similar to FIG. 28 showing therelease mechanism in a release position;

FIG. 30 is a partial side elevational view similar to FIG. 27;

FIG. 31 is a partial side elevational view similar to FIG. 27, furthershowing the removal paths of workbench sections;

FIG. 32 is a partial perspective view taken from FIG. 31, showing thekeyed member and slotted keyway of the workbench sections of the presentdisclosure;

FIG. 33 is a front perspective view showing a 90 degree workbenchconfiguration;

FIG. 34 is a partial side elevational view similar to FIG. 27, furthershowing an intermediate rotated position to achieve the 90 degreeworkbench configuration;

FIG. 35 is a partial side elevational view similar to FIG. 27, furthershowing the fully rotated position of the 90 degree workbenchconfiguration;

FIG. 36 is a partial end elevational view taken at elevation 6-6 of FIG.35;

FIG. 37 is a partial end elevational view similar to FIG. 36 showing thedisplaced condition of the release mechanism;

FIG. 38 is a partial end elevational view similar to FIG. 36 showing thebiased locked condition of the release mechanism;

FIG. 39 is a partial rear perspective view taken at view 3 of FIG. 21 ofthe hand truck position;

FIG. 40 is a partial rear perspective view modified from FIG. 39 to showan intermediate rotated position of the lift plate;

FIG. 41 is a partial rear perspective view further modified from FIG. 40to show a fully rotated and latched/stowed position of the lift plate;

FIG. 42 is a perspective view of an underside of the lift plate of thepresent disclosure showing the lift plate latching mechanism in alatched position;

FIG. 43 is a perspective view similar to FIG. 42 showing the lift platelatching mechanism in a latched position; and

FIG. 44 is a perspective view showing another aspect of a latchingmember for the toe plate of the present disclosure.

DETAILED DESCRIPTION

The following description is merely exemplary in nature and is notintended to limit the present disclosure, application, or uses.

With initial reference to FIGS. 1-4, a portable workbench 10 accordingto the present disclosure is shown. Workbench 10 generally includes atop structure 14, a support structure 18 and a collapsible frame 20.Workbench 10 is movable between a raised position, as shown in FIG. 1,and a collapsed position, as shown in FIG. 3.

With continued reference to FIGS. 1-4 and further reference to FIGS. 5and 6, top structure 14 will be described in greater detail. Topstructure 14 includes a pair of elongated mutually adjacent top members24 including upper work supporting surfaces 26 lying generally in acommon plane. Top members 24 are further defined by stationary member 28and translating member 30. Top members 24 include longitudinallyextending opposed side portions 36 defining clamping surfaces. As willbe described in greater detail, translating member 30 is adjustabletoward and away from stationary member 28 by way of a screw-typeclamping device 38.

Top members 24 are preferably made of injection molded polypropylene.Each top member 24 includes molded thereon a plurality of bore sections40 for durability. Bore sections 40 also accept accessory pegs (notshown) which increase the clamping range for larger workpieces. Theunderside of each top member 24 (FIG. 6) includes a plurality of ribsections 42 formed thereon for increased stability. Rib sections 42 areshown generally as rectangular portions but may also be arranged inother geometric shapes such as hexagonal for example. Opposing clampingdetents 46 are formed along each opposed side portion 36. Clampingdetents 46 provide a gripping function to locate a workpiece in a fixedlocation between the opposed side portion 36 or alternatively arearranged to accommodate extending portions of a workpiece. A handle 48is integrally formed on an outer edge of each top member 24. A pair ofblind bores 50 are arranged on each top member 24 for acceptingfasteners to couple support structure 18 thereto.

Recessed portions 54 arranged on the outer corners of each top member 24provide convenient locating areas for small parts such as fasteners andthe like. The transition between work surface 26 and a peripheral edge56 of top members 24 is defined by a radial contour 58. Radial contour58 provides increased stability to the top structure 14 as a whole andis also accommodating to the touch.

Turning now to FIGS. 7 and 9, support structure 18 will be described ingreater detail. Support structure 18 includes a pair of generallyC-shaped laterally disposed support members 60. Stationary member 28 iscoupled through blind bores 50 to support members 60 at mounting bores64 with conventional fasteners (not shown). Translating member 30 iscoupled through respective blind bores 50 to mounting collars 66.Mounting collars 66 are threadably journalled around respectiveadjusting rods 68. Mounting collars 66 are guided along threads formedalong adjusting rods 68 upon rotation of the adjusting rods 68.Adjusting rods 68 extend through a front passage 70 incorporated on eachsupport member 60 and terminate at handles 72. Adjusting rods 68cooperate with collars 66 to translate rotational movement of handles 72into lateral movement of translating member 30 along support members 60.In this way, cutout portion 76 accommodates the linear movement ofcollar 66 therealong. Outer edges 78 of cutout portion 76 bound mountingcollars 66 and define the maximum travel of translating member 30. Itwill be appreciated that other mechanical arrangements may be employedto translate top members 24 relative to each other in a clampingarrangement.

A handle or lever 80 is slidably coupled between support members 60 forreleasing the collapsible frame 20 from a raised position to a collapsedposition. Looped portions 84 are guided along opposing slots 86 arrangedalong a front portion 88 of support members 60. Similarly, the terminalends 90 of lever 80 extend through and are guided along slots 92incorporated on a central portion 94 of support members 60. As will bedescribed in greater detail with respect to FIG. 10, latch portion 96 oflever 80 is urged toward engagement with notches 98 formed on legs 100by biasing members 114. The cooperation of latch portions 96 withnotches 98 maintains workbench 10 in a stable raised position. Biasingmembers 114 are coupled on a first end to loop portion 84 of lever 80and a mounting extension 108 of support members 60 on a second end.Support members 60 are preferably made of a rigid material such as rollformed metal.

With reference now in general to FIGS. 1-19, collapsible frame 20incorporating linkage mechanism 110 will be described. Collapsible frame20 includes a pair of legs 100 pivotally extending between respectivesupport structure 18 and a support base 104. Legs 100 are connected onupper ends to respective support structure 18 at support member pivotpoints 120. Similarly legs 100 are connected on lower ends to respectivebase support pivot points 122. In an raised working position (FIGS. 1and 2), legs 100 separate top structure 14 and support base 104 into aparallel, spaced apart relationship. Legs 100 are laterally supported bycross brace 126. Cross brace 126 is shown having a generally U orC-shaped geometry however alternative arrangements may be employed. Aslot 130 is incorporated on each leg 100 to guide linkage mechanism 110between raised and collapsed positions. Slots 130 are preferablyarranged in a J-shaped orientation whereby linkage mechanism 110cooperates with a curved lower J-section 132 of slots 130 in a raisedposition and cooperates with a generally linear upper section 134 ofslots 130 in a collapsed position.

Support base 104 includes ground engaging support pads 140 secured onouter corners 142. Ground engaging feet 146 extend at the leg, baseintersection. Feet 146 each include an inwardly extending flange 150providing added ground gripping capability. Each flange 150 includesgripping ridges 152 formed along an upper edge. In this way, a user maystep on one or both flange 150 to provide increased workbench stability.Wheels 156 are rotatably coupled to legs 100 at the leg, baseintersection. Wheels 156 are arranged such that they are laterallydisplaced away from the ground when workbench 10 is in a raisedposition. When workbench 10 is in a collapsed position and tilted towardwheels 156 at an angle with the ground, wheels 156 engage the ground tofacilitate movement therealong. When workbench 10 is in a collapsedposition and tilted away from wheels 156, the wheels 156 are precludedfrom ground engagement. In this way, workbench 10 may be tilted againsta wall in a stable position with feet engaging the ground (FIG. 4).

Linkage mechanism 110 includes a pair of link members 160 operativelyconnecting support members 60 and legs 100. In addition, linkagemechanism 110 includes a pair of connecting members 162 operativelyconnecting support base 104 and legs 100. Each link member 160 generallyincludes an inboard and outboard slide arm 166. Slide arms 166 arecoupled on a first end for pivotal movement to respective supportmembers 60 at inboard and outboard pivot points 170. Slide arms 166 arecoupled on a second end to respective inboard and outboard posts 172.Posts 172 extend through and are translatable along slots 130 formedalong legs 100. Posts 172 are hingedly interconnected to first ends 164of respective connecting members 162 by way of links 176. Second ends168 of connecting members 162 are pivotally secured to link pivot joints178 incorporated at mounting flanges 180 extending from support base104.

The operation of linkage mechanism 110 will now be described in thecontext of moving the workbench 10 from a raised position (FIG. 1) to acollapsed position (FIG. 3). First, a user grasps lever 80 extendingunder stationary member 28 and actuates lever 80 in a direction towardthe user defining a release direction (arrow A, FIG. 7). In a firstmethod of operation, the user may place a first hand on a portion of theperipheral edge of stationary member 28 while actuating lever 80 withthe other hand. In a second method of operation, the efficiency oflinkage mechanism 110 allows a user to manipulate workbench 10 from araised position to a collapsed position with one hand. Accordingly, auser would position a thumb around peripheral edge 56 of stationarymember 28 and pull lever 80 in the release direction with the remainingfingers of the same hand.

Movement of lever 80 in the release direction disengages latch portions96 of lever 80 from notches 98 on legs 100. The user subsequentlyrotates work surface 26 upward causing support members 60 to rotateabout legs 100 at support member pivot points 120 (clockwise as viewedfrom FIG. 2). Rotational movement of support members 60 about pivotpoints 120 urges link members 166 upward along slots 130. Translation oflink members 166 along slots 130 concurrently pulls the first ends 164of connecting members 162 along the same path by way of the post andlink arrangement. Translation of first ends 164 of connecting members162 causes the second ends 168 of connecting members 162 to pivot aboutlink pivot joints 178. Such movement urges support base 104 to rotatetoward legs 100 about base pivot joints 122 (counter-clockwise as viewedfrom FIG. 2). Rotation of top structure 14 continues until posts 172engage terminal upper section 134 of slots 130.

To return the workbench 10 to a raised position from a collapsedposition a user rotates top structure 14 counterclockwise as viewed fromFIG. 4. Concurrently, link members 166 follow slot 130 toward J-section132. Top structure 14 and support base 104 expand to the generallyparallel relationship upon rotation about respective support member andbase pivot points 120, 122. Each latch 96 of lever 80 slides along anouter front surface 182 of leg 100 near notch 98 until engaging notch98. Biasing members 114 subsequently urge each latch 96 into notch 98thereby achieving a locked raised position.

With reference to FIG. 11 of the drawings, a second portable collapsibleworkbench constructed in accordance with the teachings of the presentdisclosure is generally indicated by reference numeral 10 a. Theworkbench 10 a may include a top structure 14, a support structure 18, acollapsible frame 20 a, and a toe plate 200. The top structure 14 andthe support structure 18 may be generally similar or identical to thetop structure 14 and the support structure 18, respectively, associatedwith the workbench 10 of FIG. 1 and as such, will not be discussed infurther detail herein.

In the particular example provided, the collapsible frame 20 a isgenerally similar to the collapsible frame 20 of FIG. 1. In theembodiment shown, the collapsible frame 20 a differs from thecollapsible frame 20 only in the use of a continuous axle shaft 204, aswell as the inclusion of a pair of skid plates 206. Additionally, one ormore handle assemblies 210 are preferably employed to control theworkbench 10 a when it is employed as a hand truck.

In contrast to the embodiment of FIG. 1, which employs discrete axleshafts 156 (FIG. 8) for each of the wheels 156, the exemplary embodimentillustrated employs a single, continuous axle shaft 204 thatinterconnects the wheels 156 and rotatably couples the wheels 156 to theremainder of the collapsible frame 20 a. The axle shaft 204 may serve asmount to which the toe plate 200 is rotatably mounted, as will bedescribed in greater detail, below.

The skid plates 206 may be formed from a wear resistant material with arelatively low coefficient of friction, such as nylon, ABS, polyethyleneor UHMW, and are configured to reduce the potential for damage when theworkbench 10 a is employed as a hand truck and the support base 104 ispulled against a surface, such as the edge of a stair tread.

With additional reference to FIG. 19, each of the handle assemblies 210is illustrated as including a mounting bracket 250 and a handle 252. Themounting bracket 250 is fixedly coupled to an associated one of theC-shaped laterally spaced-apart support members 60 to thereby provide acompact yet strong means for mounting an associated one of the handles252. Each handle 252 may be fixedly coupled to the mounting bracket inan orientation that permits the handles 252 to be comfortably graspedwhen the workbench 10 a is employed as a hand truck. Preferably, thehandle assemblies 210 are configured such that the handles 252 do notinterfere with the operation and use of the workbench 10 a when theworkbench 10 a is positioned in the raised position. In view of thisdisclosure, those skilled in the art will understand that the handleassemblies 210 may be configured somewhat differently. For example, thehandle assemblies 210 may be configured such that each handle 252 ispivotably or telescopically coupled to the support structure 18 so thatthey may be rotated or translated between an extended position and aretracted position.

In FIGS. 11 and 12, the toe plate 200 is illustrated as including firstand second plate portions 260 and 262, respectively, and a pair ofmounting trunnions 264 that may be disposed on the opposite lateralsides of the second plate portion 262. In the example shown, the toeplate 200 is unitarily formed form an appropriate material, such assteel plate. The first and second plate portions 260 and 262 arearranged generally perpendicular to one another.

With additional reference to FIGS. 13 and 14, the trunnions 264 areillustrated as being generally L-shaped, having a leg portion 270 and abase portion 272. The forward end of the leg portion 270 is coupled tothe second plate portion 262 while the rearward end of the leg portionis coupled to the base portion 272. A mounting aperture 276 is formedthrough the leg portion 270 and is configured to receive the axle shaft204 therethrough. Accordingly, the axle shaft 204 rotatably couples thetrunnions 264 to the collapsible frame 20 a. The base portion 272, whichextends away from the leg portion 270 in a direction away from thesecond plate portion 262, acts as a stop to inhibit rotation of thetrunnion 264 about the axle shaft 204. More specifically, contactbetween the front face 272 a of the base portion 272 and the side 100 aof an associated one of the legs 100 inhibits the rotation of the toeplate 200 in a first rotational direction beyond the lowered conditionthat is illustrated in FIGS. 11 and 13, while contact between the frontface 272 a of the base portion 272 and the end 100 b of an associatedone of the legs 100 inhibits rotation of the toe plate 200 in anopposite rotational direction beyond the raised condition that isillustrated in FIG. 12.

While the workbench 10 a has been described thus far as including anaxle shaft 204 that runs between a pair of laterally spaced-apart wheels156 to support the toe plate 200, those skilled in the art willappreciate that the disclosure, in its broader aspects, may beconstructed somewhat differently. For example, separate axle shafts 204b may be employed as shown in FIG. 15, with each axle shaft 204 bsupporting one of the wheels 156 and one of the trunnions 264.Alternatively, the separate and distinct axle shafts 156′ and 204 c maybe employed to support the wheels 156 and the trunnions 264,respectively, as shown in FIG. 16.

As a further example, the toe plate 200 may be detachably coupled to theremainder of the workbench 10 d, as shown in FIGS. 17 and 18. In thisexample, each trunnion 264 d includes a mounting barb 300 that extendsthrough a mounting hole 310 that may be formed in the leg 100 d of thecollapsible frame 20 a to permit the toe plate 200 to be removablycoupled to the collapsible frame 20 a. An optional lock pin 320, whichmay be a commercially available detent pin such as the type that ismanufactured by Carr-Lane Manufacturing Company, may be employed tofurther secure the toe plate 200 d to the workbench 10 d in a desiredlocation and/or orientation. More specifically, the lock pin 320 isinserted through apertures 322 and 324 that are formed through the leg100 d and the base portion 270 d of the trunnion 264 d, respectively.

With reference to FIGS. 20 through 23, in another preferred embodimentof the present disclosure, a portable workbench and lift truck assembly400 generally includes a top structure 402 defining a work surface 403,a lift truck structure 404, and a collapsible frame 406. Top structure402 further includes at least a first top member 408, a second topmember 410, and a third top member 412. Top members 408, 410 and 412similar to top members previously noted herein are preferably made of aninjection molded polypropylene material, however additional polymericmaterials can be used as well as wood, metal, etc. Top structure 402 iscollectively connectable to a first support structure 414 and a secondsupport structure 416, respectively.

First and second wheels 418, 420 are provided adjacent lift truckstructure 404 and provide portability for workbench and lift truckassembly 400. Lift truck structure 404 further includes a toe plate 422and a release member 424.

Collapsible frame 406 further includes first and second outer legs 426,428 and first and second inner legs 430, 432, respectively. First andsecond inner legs 430, 432 are positioned between and rotatably joinedto first and second outer legs 426,428, respectively. A first crossbrace 434 connectably joins each of first and second outer legs 426,428. A pair of fasteners 436, 437 rotatably join each of first andsecond outer legs 426, 428 to first and second inner legs 430, 432,respectively. Fasteners 436, 437 permit both rotation and translation offirst and second inner legs 430, 432 with respect to first and secondouter legs 426, 428. A second cross brace 438 and a third cross brace440 join distal ends of first inner leg 430 to second inner let 432. Inaddition, a cross brace housing 442 is substantially centrallypositioned and connectably joined to each of first and second inner legs430, 432.

Materials for first and second outer legs 426, 428, first and secondinner legs 430, 432, first cross brace 434, second cross brace 438 andcross brace housing 442 are preferably manufactured from a metalmaterial such as steel or aluminum, however with appropriate joiningmethods can be selectively made of alternate materials such as polymericmaterials. First cross brace 434, second cross brace 438 and third crossbrace 440 are preferably connected by welding.

Portable workbench and lift truck assembly 400 is movable between threebasic positions. A collapsed or substantially longitudinal position isshown in FIG. 20. A hand truck position having toe plate 422 locked atan angle to collapsible frame 406 in an extended position is shown inFIG. 21. In one preferred embodiment the angle is substantially 90degrees from a longitudinal axis of the collapsible frame 406 shown inFIG. 21. A raised position having top structure 402 positionsubstantially horizontal to a ground surface is shown in FIG. 22. In theraised position of portable workbench and lift truck assembly 400, toeplate 422 is positioned in a retracted or upright position and latchedsimilar to the collapsed position. To release portable workbench andlift truck assembly 400 from the collapsed position shown in FIG. 20, arelease lever 444 is provided which is rotatably connectable to crossbrace housing 442. Release lever 444 is rotated to permit changing fromthe collapsed to the raised position. To release toe plate 422 fromeither the upright position or the hand truck position, release member424 is displaced to unlatch toe plate 422 permitting rotation of toeplate 422 between the collapsed position and the lift plate positionshow in FIG. 21.

As best seen in FIG. 21, lift truck structure 404 further includes firstand second U-shaped brackets 446, 448. U-shaped brackets 446, 448 areused to connectably join first and second wheels 418, 420 and toe plate422 to a distal end of each of first and second outer legs 426, 428. Afirst brace rod 450 and a second brace rod 452 are connected betweenfirst cross brace 434 and each of first and second U-shaped brackets446, 448, respectively. First and second brace rods 450, 452 arepreferably welded to both first cross brace 434 and first and secondU-shaped brackets 446, 448. First brace rod 450 also includes a firstsupport end 454. Similarly, second brace rod 452 includes a secondsupport end 456. First and second supports ends 454, 456 provideadditional abutment support to an end wall 458 connected to toe plate422, when toe plate 422 is in the lift truck position shown in FIG. 21.

Referring specifically to FIG. 22, it is initially noted that second topmember 410 has been removed for clarity. First and third top members408, 412, can be displaced relative to each other but in this exampleare shown abutting with each other. In the raised position shown, bothfirst and second wheels 418, 420 and each of a distal end 460 and adistal end 462 of first and second inner legs 430, 432, respectively,provide a four point contact with the ground surface. As viewed in FIG.22, an upper end of both first and second inner legs 430, 432 rotatablyconnect via fasteners 464 and 466, respectively, to first and secondsupport structures 414 and 416. Top members 408, 412 are directlysupported by each of a surface 468 and a surface 470 of first and secondsupport structures 414, 416, respectively. Fasteners inserted througheach of a slot 472 and a slot 474, slidably support at least first topmember 408. A handle 476 is rotatably connectable to first supportstructure 414. Similarly, a handle 478 is rotatably connectable tosecond support structure 416. A pair of fasteners 480 (only one of whichis visible in FIG. 22) rotatably connect an upper end of each of firstand second outer legs 426 and 428 to first and second support structures414 and 416, respectively.

The purpose for handles 476 and 478 is to provide by rotation in eithera clockwise or a counterclockwise direction a horizontal translation ofan adjacent one of the top members. An exemplary translation of firsttop member 408 is shown in FIG. 23 which results from rotation ofhandles 476 and 478 such that first top member 408 translates in theopening direction indicated by arrow “B” with respect to third topmember 412. Top members 408 and 412 include opposing side portions 477and 479 defining clamping surfaces.

Referring now to FIG. 24, exemplary rotation paths in a clockwisedirection “C” and a counterclockwise direction “D” are shown for handle476. Similar rotation paths for handle 478 are also used.

Referring next to FIG. 25, in the collapsed position of portableworkbench and lift truck assembly 400, a total assembly height “E” isprovided as well as a total collapsed width “F”. As best seen in thisview, top structure 402 and first support structure 414 (second supportstructure 416 is not visible in this view) are both substantiallyparallel with first outer leg 426. The collapsed position is also usedfor transportation of portable workbench and lift truck assembly 400using first and second wheels 418, 420. Aligning the components ofportable workbench and lift truck assembly 400 in a generallylongitudinal configuration for the collapsed position minimizes thetotal collapsed width “F” and provides for easy storage of portableworkbench and lift truck assembly 400.

As best seen in FIG. 26, to change between the collapsed and raisedpositions of portable workbench and lift truck assembly 400, releaselever 444 is first repositioned from the biased position shown in FIG.20. After release lever 444 is repositioned, top structure 402 can berotated about fastener pair 480 about a rotation arc “G”. As topstructure 402 rotates about an axis of rotation formed through fasteners480, fasteners 436 and 437 guide each of first and second inner legs 430and 432 in a sliding direction “H”. Fasteners 436 and 437 are slidablydisposed within a slot 482 formed in each of first and second inner legs430 and 432 (second inner leg 432 is not visible in this view). Toprovide stability during this rotation procedure, a base end 484 isprovided at distal ends of each of first and second outer legs 426 and428. Base ends 484 prevent contact of either first or second wheels 418or 420 with the ground, thus providing a stable contact for portableworkbench and lift truck assembly 400 during the rotation phase.

As seen in FIG. 27, when top structure 402 has rotated about rotationarc “G” until fasteners 436 contact a slot distal end 485 (shown in FIG.26) of slots 482, collapsible frame 406 substantially forms an X shapeas shown. In the raised position, each of the base ends 484 and thedistal ends 460 and 462 contact the ground surface forming a plane 486.In this position, top structure 402 is positioned parallel to a plane488 which is substantially parallel to plane 486, thus providing a flatwork surface for top structure 402.

A latch mechanism 489 associated with release lever 444 is substantiallyenclosed within a first housing wall 490 and a second housing wall 492of cross brace housing 442. Release lever 444 is connected to a leverarm 494. Lever arm 494 is rotatably connected to second housing wall 492via a pin 496. A first rod 498 is rotatably connected to lever arm 494at a distal end via a fastener 500. A second rod 502 is rotatablyconnectable to lever arm 494 above pin 496 as seen in FIG. 28 viafastener 504. A biasing element 506 normally biases release lever 444 ina biasing direction of arrow “J”. Biasing element 506 is connectedbetween lever arm 494 and second housing wall 492. In the latchedposition shown, first rod 498 is biased by biasing element 506 intosliding engagement within an aperture 508 formed within first outer leg426. Similarly, second rod 502 is biased into sliding engagement withinan aperture 510 formed within second outer leg 428. Latched engagementof first rod 498 and second rod 502 prevents rotation of first andsecond outer legs 426, 428 relative to first and second inner legs 430,432, which therefore latches portable workbench and lift truck assembly400 in the collapsed position. A guard 512 is connectably joined tosecond housing wall 492 and is positionable between release lever 444and top structure 402. Guard 512 prevents inadvertent contact with andrelease of release lever 444.

Referring to FIG. 29, an un-latched position of latch mechanism 489 isshown. To reach the un-latched position, release lever 444 is rotated ina release directional arc “K” which has as its axis of rotation pin 496.First rod 498 is displaced in a release direction “M”. Second rod 502 isdisplaced in a release direction “L”. By disengaging each of first andsecond rods 498, 502 from apertures 508, 510, respectively, first andsecond inner legs 430, 432 can be rotated relative to first and secondouter legs 426, 428. As release lever 444 is rotated, an increasedbiasing forced is created by a biasing element 506. When release lever444 is released, the biasing force of biasing element 506 tends toreposition release element 444 back to its latched position. Releaselever 444 can therefore be held by biasing element 506 in the positionshown in FIG. 29 during the final phase of collapsing collapsible frame406 until first and second rods 498, 502 realign with apertures 508 and510, respectively.

Referring generally to FIGS. 30 through 32, a method to install orremove individual members of top structure 402 is identified. From theposition of top structure 402 shown in FIG. 27, each of handles 476 and478 are rotated in the counterclockwise direction “D” such that firsttop member 408 is displaced in the opening direction “B” creating aclearance gap “N” between first top member 408 and both second and thirdtop members 410 and 412. Either or both of second and third top members410 and 412 can then be displaced to the left as shown in FIG. 31 topermit release or relocation of either or both second and third topmembers 410 and 412. For example, a sub-assembly 514 including bothsecond and third top members 410 and 412 can be translated for removalor relocation.

Second top member 410 is connectably joined to a spacer 516. Spacer 516further has a keyed pin 518 extending therefrom. Similarly, third topmember 412 is connectably joined to a spacer 520 which similarly has akeyed pin 522 extending therefrom. Sub-assembly 514 is translated intothe clearance gap “N” to release the sub-assembly. As further detailedin FIG. 32, each keyed pin 518, 522 (only keyed pin 518 is visible inthis view) further includes a first and second wing 524, 526. Anexemplary pair of key slots 528, 530 are created in both first supportstructure 414 and support member 532. To releasably engage one of thetop members to either of first or second support structures 414, 416,the keyed pin is inserted into key slot 528 (or key slot 530) until bothfirst and second wings 524 and 526 are below an elevation of supportmember 532. The top member is then pushed in the key engagementdirection “P” engaging first and second wings 524, 526 with the supportstructure, preventing direct removal of the top member.

As seen in FIG. 33, an upright top member configuration 534 is shown. Inthe exemplary upright top member configuration 534 shown, first topmember 408 is positioned substantially perpendicular to second topmember 410. A pair of dogs 536 are also shown. Each of the dogs 536includes at least one deflectable end 538 which releasably engageswithin an aperture 540 of one of the top members. Dogs 536 provide areleasable stop for work items placed on top structure 402. Dogs 536 canbe releasably positioned in any of a plurality of apertures 540 formedin each of the top members of top structure 402.

To transition from the top structure 402 configuration shown in FIG. 27to the upright top member configuration 534 shown in FIG. 33, first topmember 408 is first translated to create clearance gap “N”. To releasesupport members 532 from first and second support structures 414 and416, each of a pair of release toggles 542 connected to opposing ones ofthe support members 532 is translated in a displacement direction “R”until release toggles 542 physically displace from within an engagementslot 544 formed in a distal end of each of first and second supportstructures 414 and 416. Support members 532 are rotatably connected toeach of first and second support structures 414 and 416 by a fastener546. Each of the pair of support members 532 are then rotated about anarc “S”. An axis of rotation 548 for arc “S” is formed through eachfastener 546. A biased catch 550 is provided at a distal end of each ofthe support members 532. Biased catch 550 is slidably disposed within aslotted pathway 552. As each support member 532 rotates about arc “S”,biased catch 550 rotates within slotted pathway 552.

As best seen in FIG. 35, both release toggle 542 and biased catch 550are normally biased in the biased return direction “T”. When supportmember 532 reaches the upright top member configuration 534, biasedcatch 550 slidably engages within a first slot 554 created withinslotted pathway 552. Biased catch 550 positioned within first slot 554subsequently prevents inadvertent rotation of support members 532. Asecond slot 556 is also created at the opposite end of slotted pathway552 from first slot 554 for engagement by biased catch 550 when supportmembers 532 are in the horizontal position substantially parallel withplane 488. After support members 532 reach the vertical position shownin FIG. 35, first top member 408 is directed by rotation of handles 476and 478 in the downward direction as viewed in FIG. 35 until first topmember 408 contacts second top member 410. Handles 476 and 478 arerotated in the clockwise rotation direction “C” during this translation.

Referring generally to FIGS. 36 through 38, a displacement mechanism 557includes release toggle 542 connectably joined to biased catch 550.Release toggle 542 includes a toggle body 558. A pin 560 disposedthrough toggle body 558 connectably joins a release rod 562 to togglebody 558. Release rod 562 is positioned generally parallel to a threadedrod 564 which is connectably disposed to handle 476 (a similarconfiguration is also used for handle 478) acting as a clamping deviceto engage opposing top surfaces. Release rod 562 is positioned toslidably clear threaded rod 564. Biased catch 550 is connected at adistal end of release rod 562. A biasing element 566 is connectedbetween first support structure 414 and release rod 562 to provide anormal biasing force for release rod 562 in a biased return direction“T”. Displacing release toggle 542 in the displacement direction “R”,also displaces biased catch 550, which tensions biasing element 566. Thebiasing force generated by tensioning biasing element 566 thereafterreturns release toggle 542 in the biased return direction “T” after theoperator releases release toggle 542.

Referring generally to FIGS. 39 through 41, various positions for toeplate 422 are shown. In the lift truck position, toe plate 422 isrotated approximately 90 degrees from a longitudinal axis 567 of firstand second outer legs 426 and 428. Toe plate 422 is latched in thisposition which allows portable workbench and lift truck assembly 400 tostand vertically upright as shown in FIG. 21. End wall 458 of lift plate22 physically contacts first and second support ends 454 and 456 offirst and second brace rods 450 and 452, respectively. A biasing forceapplied to release member 424 in the biasing force direction “U” retainsthe latched position for toe plate 422 until release member 424 isdisplaced, generally to the right as viewed in FIG. 40 in a displacementdirection “V”.

In one preferred embodiment of the present disclosure, toe plate 422includes a plurality of reinforcement ribs 568 which are raised from asurrounding plate surface of toe plate 422. To release the toe plate 422from the lift truck configuration shown in FIG. 39, release member 424is displaced by the operator in displacement direction “V” either byfoot or by hand. The operator then directs a displacement force at endwall 458, for example by foot pressure, in the rotation direction “X”.This induces toe plate 422 to rotate about an arc “W” until toe plate422 reaches the generally vertical position shown in FIG. 41. A biasingforce normally applied to release member 424 in the biasing forcedirection “U” causes toe plate 422 to latch when the vertical positionis reached as will be described in further detail below. In the latchedupright position, toe plate 422 is positioned substantially parallel tolongitudinal axis 567 of both first and second outer legs 426 and 428.

Referring generally to FIGS. 42 and 43, a lift plate latch mechanism 569is detailed. Lift plate latch mechanism 569 includes a member body 570connected to release member 424. Member body 570 is substantiallypositioned below an under surface 572 of toe plate 422 as viewed in FIG.42. Two pins 574, 576 extend through and outwardly from member body 570to retain the position of member body 570 below under surface 572.Member body 570 is generally configured in a rectangular shape and isslidably disposed within a rectangular aperture 578 created in toe plate422. In the latched position shown in FIG. 42, member body 570 contactsa first abutment end 580 of rectangular aperture 578. Member body 570further includes a pin 582 disposed through member body 570. Pin 582mechanically connects a hooked catch 584 to member body 570. A biasingmember 586 is connected to hooked catch 584 at a first end and isconnected to a bracket 588 at a second end. Bracket 588 is joined tounder surface 572 via a pair of fasteners 590 and 592, respectively. Aclearance aperture 593 is provided in the flange leg of bracket 588 toslidably support a rod 594 there through. A first end of rod 594 is alsoconnected together with hooked catch 584 to member body 570 using pin582. A distal end 596 of rod 594 is slidably disposed through aclearance aperture 598 formed in an end support wall 600 of toe plate422. The biasing force created by biasing member 586 normally positionsrod 594 within one of a pair of apertures (not shown) provided in secondU-shaped bracket 448. The pair of apertures of second U-shaped bracket448 are positioned such that capture of rod 594 latches toe plate 422 ineither the lift truck position or the upper latched position shown inFIG. 41. Toe plate 422 is rotatably connected to each first and secondU-shaped bracket 446 and 448 by a pin 602 (only a first one is shown).

To release toe plate 422 from a latched position using lift plate latchmechanism 569, release member 424 is displaced in the displacementdirection “V” (to the right as viewed in FIG. 43) until an end face 604of member body 570 contacts a second abutment end 606 of rectangularaperture 578. At this location of member body 570, distal end 596 of rod594 is withdrawn from engagement with one of the apertures in secondU-shaped bracket 448. At this time, distal end 596 is positionedapproximately parallel to end support wall 600 providing clearance tosecond U-shaped bracket 448 for rotation of toe plate 422 about pin 602.Once distal end 596 disengages from the aperture of second U-shapedbracket 448 and toe plate 422 is in an intermediate rotation position,release member 424 can be released and the biasing force of biasingmember 586 will direct distal end 596 and rod 594 to reengage thesubsequent aperture in second U-shaped bracket 448.

Referring finally to FIG. 44, in another aspect of the presentdisclosure, toe plate 422 is provided with a latch member acting as ahook to positively engage first support end 454 of first brace rod 450.In this aspect, a tapered slide 608 connected to release member 424 istranslated by release member 424 in the displacement direction “V”. Anincreasing thickness of tapered slide 608 displaces a U-shaped portion610 of a rod 612 in a downward direction as viewed in FIG. 44. Rod 612includes a hook 614 at a distal end which rotates in response torotation of U-shaped portion 610 generally counterclockwise as viewed inFIG. 44 in the arc direction “Y”. Rotation in arc direction “Y” causeshook 614 to disengage from first support end 454. When release member424 is released, a biasing force from biasing member 586 directs releasemember 424 to return in the direction “U” (as shown in FIG. 42) and abiasing force such as from a torsional biasing member (not shown)induces a clockwise rotation of hook 614 as viewed in FIG. 44. If toeplate 422 is positioned in the lift truck position, hook 614 engagesfirst support end 454. When hook 614 is disengaged from first supportend 454, toe plate 422 can be rotated to the upright position shown inFIG. 20. Hook 614 therefore provides an additional latching point forlatch toe plate 422 in the lift or hand truck position.

Those skilled in the art can now appreciate from the foregoingdescription that the broad teachings of the present disclosure can beimplemented in a variety of forms. For example, the workbench disclosedherein is described having slidable link members cooperating on each legof the collapsible frame. It is envisioned however that the workbenchmay alternatively incorporate a single linkage cooperating with one legwhile reaching similar results. Biasing elements 506, 566 and 586 areshown as coiled springs which are generally provided in spring steelmaterial. Different biasing devices and/or materials can also be used.Pins 574, 575 and 582 can also be replaced with metal clips or polymericparts.

Accordingly, while the disclosure has been described in thespecification and illustrated in the drawings with reference to severalpreferred embodiments, it will be understood by those skilled in the artthat various changes may be made and equivalents may be substituted forelements thereof without departing from the scope of the disclosure. Inaddition, many modifications may be made to adapt a particular situationor material to the teachings of the disclosure without departing fromthe essential scope thereof. For example, the position of latchmechanism 569 and/or displacement mechanism 557 can be reversed from thepositions shown. Additional fixed handles can also used to assist usingthe folding bench with hand truck of the present disclosure for exampleduring use in the hand truck position. Therefore, it is intended thatthe disclosure not be limited to the particular embodiment illustratedby the drawings and described in the specification as the best modepresently contemplated for carrying out this disclosure, but that thedisclosure will include any embodiments falling within the foregoingdescription and the appended claim.

1. A portable workbench, comprising: a plurality of top members defining a working surface; a support structure supporting the top members and including a clamping device for selectively traversing at least one of the top members toward another of the top members to permit a workpiece to be selectively clamped there between; a collapsible frame connectable to the support structure; a pair of wheels coupled to the frame; a toe plate rotatably coupled to the frame and positionable in each of a retracted and an extended position; and a latching mechanism operable to latch the toe plate in at least the retracted position; wherein the portable workbench is positionable in a raised position in frictional contact with a ground surface and a collapsed position having the wheels in contact with the ground surface for translation of the portable workbench, and wherein the toe plate is movable from the retracted position to the extended position to permit the portable workbench to be further employed as a hand truck.
 2. The portable workbench of claim 1, wherein the frame further comprises first and second leg members, the leg members being rotatably joined to each other.
 3. The portable workbench of claim 2, wherein the frame further comprises frame portions wherein only the frame portions contact the ground surface when the frame is in the raised position.
 4. The portable workbench of claim 3, wherein the pair of wheels are connected to the frame proximate to selected ones of the frame portions such that the pair of wheels are positioned above the ground surface in the raised position.
 5. The portable workbench of claim 2, wherein the pair of wheels are rotatably coupled proximate a ground contacting end of the frame.
 6. The portable workbench of claim 1, further comprising at least one handle connected to the frame operable for an operator to grasp to control the portable workbench when the toe plate is in the extended position.
 7. The portable workbench of claim 1, wherein the plurality of top members includes first and second top members, the first top member.
 8. A portable workbench, comprising: a plurality of top members defining a working surface; a support structure supporting the top members and including a clamping device; a collapsible frame connectable to the support structure, the collapsible frame having legs rotatably connectable to each other and positionable substantially parallel to each other in a workbench collapsed position and an extended position; a pair of wheels rotatably coupled to the frame; a toe plate rotatably coupled to the frame positionable in at least in an upright position substantially parallel to the frame when in the substantially parallel position, and a rotated extended position; and a latching mechanism operable to latch the toe plate in at least the upright position; wherein the portable workbench is positionable in each of a raised position having the collapsible frame in the extended position, the collapsed position having both the toe plate and the working surface positioned substantially parallel to the frame, and a lift truck position modified from the collapsed position having the toe plate in the extended position rotated approximately 90 degrees from a longitudinal axis of the frame.
 9. The portable workbench of claim 8, further comprising a release mechanism operable to latch the collapsible frame in the collapsed position.
 10. The portable workbench of claim 8, further comprising first and second handles rotatable to displace at least one of the top members both toward and away from a second one of the top members.
 11. The portable workbench of claim 8, further comprising a foot actuated member operable to assist manual rotation of the latching device.
 12. The portable workbench of claim 8, further comprising a base portion rigidly extendable from the toe plate, the base portion operable to contact the frame when the toe plate is positioned in the extended position, and further operable to prevent continued rotation of the toe plate beyond the extended position.
 13. A method for constructing a portable workbench, the workbench including a plurality of top members defining a working surface, a support structure supporting the top members, a collapsible frame; at least one wheel; and a toe plate; the method comprising: movably connecting at least one of the top members to the support structure; joining the support structure to the collapsible frame; rotatably fastening the wheel to the collapsible frame; rotatably coupling the toe plate to the collapsible frame; connecting a latching mechanism to the toe plate operable to releasably latch the toe plate in each of a stowed and an extended position; and collapsibly joining a plurality of legs to create the collapsible frame.
 14. The method of claim 13, further comprising connecting a pair of rotatable handles to the portable workbench operable to translate the movably connected at least one of the top members.
 15. The method of claim 13, further comprising connecting a release mechanism to the collapsible frame operable to latch the legs in a portable workbench collapsed position.
 16. The method of claim 13, further comprising connecting hand grip members to the portable workbench. 